The combination of 1-octyl-3-methylimidazolium tetrafluorborate with TBAB or THF on CO2 hydrate formation and CH4 separation from biogas 被引量：4

The combination of 1-octyl-3-methylimidazolium tetrafluorborate with TBAB or THF on CO_2 hydrate formation and CH_4 separation from biogas

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摘要 [C_8min] BF_4 was used in this work to combine with TBAB or THF for the investigation about thermodynamic and kinetic additives on CO_2 and CH_4/CO_2 hydrates. The results show that [C_8min] BF_4 has the inhibition effect on the equilibrium of hydrate formation. About the kinetic study, [C_8 min] BF_4 could improve the rate of CO_2 hydrate formation and increase the gas uptake in hydrate phase. At the same time, the combination of TBAB and [C8 min] BF_4 could increase the mole friction of CH_4 in residual gas comparing with the data in THF solution. CH_4 separation efficiency was strongly enhanced. Since that the size of CO_2 and CH_4 molecules are similar, CH_4 and CO_2 could form the similar hydrate, so the recovery of CH_4 from biogas decreases lightly. The CH_4 content in biogas can purified from 67 mol% to 77 mol% after one-stage hydrate formation. In addition, the combination of THF and[C_8 min] BF_4 do not have obvious promoting effect on CH_4 separation comparing with the gas separation results in pure THF solution. [C_8min] BF_4 was used in this work to combine with TBAB or THF for the investigation about thermodynamic and kinetic additives on CO_2 and CH_4/CO_2 hydrates. The results show that [C_8min] BF_4 has the inhibition effect on the equilibrium of hydrate formation. About the kinetic study, [C_8 min] BF_4 could improve the rate of CO_2 hydrate formation and increase the gas uptake in hydrate phase. At the same time, the combination of TBAB and [C8 min] BF_4 could increase the mole friction of CH_4 in residual gas comparing with the data in THF solution. CH_4 separation efficiency was strongly enhanced. Since that the size of CO_2 and CH_4 molecules are similar, CH_4 and CO_2 could form the similar hydrate, so the recovery of CH_4 from biogas decreases lightly. The CH_4 content in biogas can purified from 67 mol% to 77 mol% after one-stage hydrate formation. In addition, the combination of THF and[C_8 min] BF_4 do not have obvious promoting effect on CH_4 separation comparing with the gas separation results in pure THF solution.

作者 Gang Yue Aixian Liu Qiang Sun Xingxun Li Wenjie Lan Lanying Yang Xuqiang Guo

机构地区 State Key Iaboratory of Heavy Oil Processing China University of Petroleum-Beijing China University of Petroleum-Beijing At Karamay

出处《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2018年第12期2495-2502,共8页 中国化学工程学报（英文版）

关键词 BIOGAS Gas SEPARATION HYDRATE Ionic liquid Biogas Gas separation Hydrate Ionic liquid

分类号 TQ [化学工程]

作者简介 Corresponding author at:Xuqiang Guo,State Key laboratory of Heavy Oil Processing,China University of Petroleum,Beijing 102249,China. E-mail address:guoxq@cup.edu.cn.

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